Digital projector using arrayed light sources

ABSTRACT

A beam alignment chamber extending in a length direction comprising a base having a front edge, and two side edges, first and second opposed side walls connected to the base, and extending along the length of the base, a front wall located at the front edge of the base having an output opening. The beam alignment chamber further comprises a plurality of arrays of light sources disposed to direct light beams through the first or second side walls, and a plurality of reflectors mounted on the base, each having independent yaw and pitch adjustments, each reflector being paired with a corresponding array of light sources, the base-mounted reflectors being disposed to direct the light beams along the length of the beam alignment chamber through the output opening forming an aligned two-dimensional array of parallel light beams.

CROSS REFERENCE TO RELATED APPLICATIONS

The present invention is related to commonly assigned U.S. patentapplication entitled “Projection Apparatus Using Solid-State LightSource Array” filed Nov. 9, 2007 by Silverstein et al., Ser. No.11/937,729; to commonly assigned U.S. patent application entitled“Uniform Speckle Reduced Laser Projection Using Spatial and TemporalMixing” filed May 15, 2008 by Silverstein et al., Ser. No. 12/121,185;and to commonly assigned U.S. patent application entitled “BeamAlignment Chamber Providing Divergence Correction” filed herewith bySilverstein et al., Ser. No. 12/432,999.

FIELD OF THE INVENTION

This invention generally relates to an apparatus for projecting adigital image and more particularly relates to an improved apparatus andmethod for aligning solid state lasers as illumination sources.

BACKGROUND OF THE INVENTION

In order to be considered suitable to replace conventional filmprojectors, digital projection systems, particularly multicolorcinematic projection systems, must meet demanding requirements for imagequality and performance. Among other features, this means highresolution, wide color gamut, high brightness, and frame-sequentialcontrast ratios exceeding 1,000:1.

The most promising solutions for multicolor digital cinema projectionemploy, as image forming devices, one of two basic types of spatiallight modulators (SLMs). The first type of spatial light modulator isthe Digital Light Processor (DLP) a digital micromirror device (DMD),developed by Texas Instruments, Inc., Dallas, Tex. DLP devices aredescribed in a number of patents, for example U.S. Pat. No. 4,441,791;U.S. Pat. No. 5,535,047; U.S. Pat. No. 5,600,383 (all to Hornbeck); andU.S. Pat. No. 5,719,695 (Heimbuch). Optical designs for projectionapparatus employing DLPs are disclosed in U.S. Pat. No. 5,914,818(Tejada et al.); U.S. Pat. No. 5,930,050 (Dewald); U.S. Pat. No.6,008,951 (Anderson); and U.S. Pat. No. 6,089,717 (Iwai). DLPs have beensuccessfully employed in digital projection systems.

FIG. 1 shows a simplified block diagram of a projector apparatus 10 thatuses DLP spatial light modulators. A light source 12 providespolychromatic light into a prism assembly 14, such as a Philips prism,for example. Prism assembly 14 splits the polychromatic light into red,green, and blue component bands and directs each band to thecorresponding spatial light modulator 20 r, 20 g, or 20 b. Prismassembly 14 then recombines the modulated light from each SLM 20 r, 20g, and 20 b and provides this light to a projection lens 30 forprojection onto a display screen or other suitable surface.

Although DLP-based projectors demonstrate the capability to provide thenecessary light throughput, contrast ratio, and color gamut for mostprojection applications from desktop to large cinema, there are inherentresolution limitations, with current devices providing only 2148×1080pixels. In addition, high component and system costs have limited thesuitability of DLP designs for higher-quality digital cinema projection.Moreover, the cost, size, weight, and complexity of the Philips or othersuitable prisms as well as the fast projection lens with a long workingdistance required for brightness are inherent constraints with negativeimpact on acceptability and usability of these devices.

A second type of spatial light modulator used for digital projection isthe LCD (Liquid Crystal Device). The LCD forms an image as an array ofpixels by selectively modulating the polarization state of incidentlight for each corresponding pixel. LCDs appear to have advantages asspatial light modulators for high-quality digital cinema projectionsystems. These advantages include relatively large device size,favorable device yields and the ability to fabricate higher resolutiondevices, for example 4096×2160 resolution devices by Sony and JVCCorporations. Among examples of electronic projection apparatus thatutilize LCD spatial light modulators are those disclosed in U.S. Pat.No. 5,808,795 (Shimomura et al.); U.S. Pat. No. 5,798,819 (Hattori etal.); U.S. Pat. No. 5,918,961 (Ueda); U.S. Pat. No. 6,010,121 (Maki etal.); and U.S. Pat. No. 6,062,694 (Oikawa et al.). LCOS (Liquid CrystalOn Silicon) devices are thought to be particularly promising forlarge-scale image projection. However, LCD components have difficultymaintaining the high quality demands of digital cinema, particularlywith regard to color and contrast, as the high thermal load of highbrightness projection affects the materials polarization qualities.

A continuing problem with illumination efficiency relates to etendue or,similarly, the Lagrange invariant. As is well known in the optical arts,etendue relates to the amount of light that can be handled by an opticalsystem. Potentially, the larger the etendue, the brighter the image.Numerically, etendue is proportional to the product of twocharacteristics, namely the image area and the numerical aperture. Interms of the simplified optical system represented in FIG. 2 havinglight source 12, optics 18, and a spatial light modulator 20, etendue isa factor of the area of the light source A1 and its output angle θ1 andis equal to the area of the modulator A2 and its acceptance angle θ2.For increased brightness, it is desirable to provide as much light aspossible from the area of light source 12. As a general principle, theoptical design is advantaged when the etendue at the light source ismost closely matched by the etendue at the modulator.

Increasing the numerical aperture, for example, increases etendue sothat the optical system captures more light. Similarly, increasing thesource image size, so that light originates over a larger area,increases etendue. In order to utilize an increased etendue on theillumination side, the etendue must be greater than or equal to that ofthe illumination source. Typically, however, the larger the image, themore costly and sizeable the optics and support components. This isespecially true of devices such as LCOS and DLP components, where thesilicon substrate and defect potential increase with size. As a generalrule, increased etendue results in a more complex and costly opticaldesign. Using an approach such as that outlined in U.S. Pat. No.5,907,437 (Sprotbery et al.) for example, lens components in the opticalsystem must be designed for large etendue. The source image area for thelight that must be converged through system optics is the sum of thecombined areas of the spatial light modulators in red, green, and bluelight paths; notably, this is three times the area of the finalmulticolor image formed. That is, for the configuration disclosed inU.S. Pat. No. 5,907,437, optical components handle a sizable image area,therefore a high etendue, since red, green, and blue color paths areseparate and must be optically converged. Moreover, although aconfiguration such as that disclosed in U.S. Pat. No. 5,907,437 handleslight from three times the area of the final multicolor image formed,this configuration does not afford any benefit of increased brightness,since each color path contains only one-third of the total light level.

Efficiency improves when the etendue of the light source is well-matchedto the etendue of the spatial light modulator. Poorly matched etenduemeans that the optical system is either light-starved, unable to providesufficient light to the spatial light modulators, or inefficient,effectively discarding a substantial portion of the light that isgenerated for modulation.

The goal of providing sufficient brightness for digital cinemaapplications at an acceptable system cost has thus far proved elusive todesigners of both LCD and DLP systems. LCD-based systems have beencompromised by the requirement for polarized light, reducing efficiencyand increasing etendue, even where polarization recovery techniques areused. DLP device designs, not requiring polarized light, have proven tobe somewhat more efficient, but still require expensive, short livedlamps and costly optical engines, making them too expensive to competeagainst conventional cinema projection equipment.

In order to compete with conventional high-end film-based projectionsystems and provide what has been termed electronic or digital cinema,digital projectors must be capable of achieving comparable cinemabrightness levels to this earlier equipment. As some idea of scale, thetypical theatre requires on the order of 10,000 lumens projected ontoscreen sizes on the order of 40 feet in diagonal. The range of screensrequires anywhere from 5,000 lumens to upwards of 40,000 lumens. Inaddition to this demanding brightness requirement, these projectors mustalso deliver high resolution (2048×1080 pixels) and provide around2000:1 contrast and a wide color gamut.

Some digital cinema projector designs have proved to be capable of thislevel of performance. However, high equipment and operational costs havebeen obstacles. Projection apparatus that meet these requirementstypically cost in excess of $50,000 each and utilize high wattage Xenonarc lamps that need replacement at intervals between 500-2000 hours,with typical replacement cost often exceeding $1000. The large etendueof the Xenon lamp has considerable impact on cost and complexity, sinceit necessitates relatively fast optics to collect and project light fromthese sources.

One drawback common to both DLP and LCOS LCD spatial light modulators(SLM) has been their limited ability to use solid-state light sources,particularly laser sources. Although they are advantaged over othertypes of light sources with regard to relative spectral purity andpotentially high brightness levels, solid-state light sources requiredifferent approaches in order to use these advantages effectively.Conventional methods and devices for conditioning, redirecting, andcombining light from color sources, used with earlier digital projectordesigns, can constrain how well laser array light sources are used.

Solid-state lasers promise improvements in etendue, longevity, andoverall spectral and brightness stability but, until recently, have notbeen able to deliver visible light at sufficient levels and within thecost needed to fit the requirements for digital cinema. In a more recentdevelopment, VCSEL laser arrays have been commercialized and show somepromise as potential light sources. However, the combined light from asmany as 9 individual arrays is needed in order to provide the necessarybrightness for each color.

Examples of projection apparatus using laser arrays include thefollowing:

U.S. Pat. No. 5,704,700 entitled “Laser Illuminated Image ProjectionSystem and Method of Using Same” to Kappel et al. describes the use of amicrolaser array for projector illumination.

Commonly assigned U.S. Pat. No. 6,950,454 to Kruschwitz et al. entitled“Electronic Imaging System Using Organic Laser Array Illuminating anArea Light Valve” describes the use of organic lasers for providinglaser illumination to a spatial light modulator.

U.S. Patent Publication No. 2006/0023173 entitled “Projection DisplayApparatus, System, and Method” to Mooradian et al. describes the use ofarrays of extended cavity surface-emitting semiconductor lasers forillumination;

U.S. Pat. No. 7,052,145 entitled “Displays Using Solid-State LightSources” to Glenn describes different display embodiments that employarrays of microlasers for projector illumination.

U.S. Pat. No. 6,240,116 entitled Laser Diode Array Assemblies WithOptimized Brightness Conservation” to Lang et al. discusses thepackaging of conventional laser bar- and edge-emitting diodes with highcooling efficiency and describes using lenses combined with reflectorsto reduce the divergence-size product (etendue) of a 2 dimensional arrayby eliminating or reducing the spacing between collimated beams.

There are difficulties with each of these types of solutions. Kappel'700 teaches the use of a monolithic array of coherent lasers for use asthe light source in image projection, whereby the number of lasers isselected to match the power requirements of the lumen output of theprojector. In a high lumen projector, however, this approach presents anumber of difficulties. Manufacturing yields drop as the number ofdevices increases and heat problems can be significant with larger scalearrays. Coherence can also create problems for monolithic designs.Coherence of the laser sources typically causes artifacts such asoptical interference and speckle. It is, therefore, preferable to use anarray of lasers where coherence, spatial and temporal coherence is weakor broken. While a spectral coherence is desired from the standpoint ofimproved color gamut, a small amount of broadening of the spectrum isalso desirable for removing the sensitivity to interference and speckleand also lessens the effects of color shift of a single spectral source.This shift could occur, for example, in a three color projection systemthat has separate red, green and blue laser sources. If all lasers inthe single color arrays are tied together and of a narrow wavelength anda shift occurs in the operating wavelength, the white point and color ofthe entire projector may fall out of specification. On the other hand,where the array is averaged with small variations in the wavelengths,the sensitivity to single color shifts in the overall output is greatlyreduced. While components may be added to the system to help break thiscoherence as discussed by Kappel, it is preferred from a cost andsimplicity standpoint to utilize slightly varying devices from differingmanufactured lots to form a substantially incoherent laser source.Additionally reducing the spatial and temporal coherence at the sourceis preferred, as most means of reducing this incoherence beyond thesource utilizes components such as diffusers, which increase theeffective extent of the source (etendue), cause additional light loss,and add expense to the system. Maintaining the small etendue of thelasers enable a simplification of the optical train, which is highlydesired.

Laser arrays of particular interest for projection applications arevarious types of VCSEL (Vertical Cavity Surface-Emitting Laser) arrays,including VECSEL (Vertical Extended Cavity Surface-Emitting Laser) andNECSEL (Novalux Extended Cavity Surface-Emitting Laser) devices fromNovalux, Sunnyvale, Calif. However, conventional solutions using thesedevices are prone to a number of problems. One limitation relates todevice yields. Due largely to heat and packaging problems for criticalcomponents, the commercialized VECSEL array is extended in length, butlimited in height; typically, a VECSEL array has only two rows ofemitting components. The use of more than two rows tends to dramaticallyincrease yield difficulties. This practical limitation would make itdifficult to provide a VECSEL illumination system for projectionapparatus as described in U.S. Pat. No. 7,052,145, for example.Brightness would be constrained when using the projection solutionsproposed in U.S Patent Publication No. 2006/0023173. Although Kruschwitzet al., U.S. Pat. No. 6,950,454 and others describe the use of laserarrays using organic VCSELs, these organic lasers have not yet beensuccessfully commercialized. In addition to these problems, conventionalVECSEL designs are prone to difficulties with power connection and heatsinking. These lasers are of high power; for example, a single row laserdevice, frequency doubled into a two row device from Novalux producesover 3 W of usable light. Thus, there can be significant currentrequirements and heat load from the unused current. Lifetime and beamquality is highly dependent upon stable temperature maintenance.

Coupling of the laser sources to the projection system presents otherdifficulties that are not adequately addressed using conventionalapproaches. For example, using Novalux NECSEL lasers, approximately nine2 row by 24 laser arrays are required for each color in order toapproximate the 10,000 lumen requirement of most theatres. It isdesirable to mount these sources separately in order to providesufficient heat dissipation as well as for running power and controlsignals and allowing modular design that simplifies servicing andreplacement. At the same time, however, it is necessary to combine thelaser beams from multiple sources in order to form a single beam thatprovides collimated light. Solutions that overlay individual beams losesome of the generated light due to inefficiencies in beam-combiningcoatings. Any angular component introduced in the combining processincreases the etendue and is generally undesirable. Redirecting multiplebeams with minimal spacing between beams is desirable, but not easilyachieved using conventional beam-combining techniques.

Thus, it can be seen that there is a need for illumination solutionsthat capitalize on the advantages of solid-state array light sources andallow effective use of solid-state illumination components with DLP andLCOS modulators.

SUMMARY OF THE INVENTION

The present invention addresses the need for improved brightness forprojection display by providing a beam alignment chamber extending in alength direction comprising:

a base having a front edge, and two side edges;

first and second opposed side walls connected to the base, and extendingalong the length of the base;

a front wall located at the front edge of the base having an outputopening;

a plurality of arrays of light sources disposed to direct light beamsthrough the first or second side walls; and

a plurality of reflectors mounted on the base, each having independentyaw and pitch adjustments, each reflector being paired with acorresponding array of light sources, the base-mounted reflectors beingdisposed to direct the light beams along the length of the beamalignment chamber through the output opening forming an alignedtwo-dimensional array of parallel light beams.

It is a feature of the present invention that it provides an apparatusand method for laser beam alignment that provides a two-dimensionalarray of parallel output beams from a plurality of arrays of lightsources.

It is an advantage of the present invention that it provides anapparatus for compact packaging of multiple laser light arrays, aligningthe arrays in parallel along an output light path.

These and other features and advantages of the present invention willbecome apparent to those skilled in the art upon a reading of thefollowing detailed description when taken in conjunction with thedrawings wherein there is shown and described an illustrative embodimentof the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic block diagram of a conventional projectionapparatus using a combining prism for the different color light paths;

FIG. 2 is a representative diagram showing etendue for an opticalsystem;

FIG. 3A is a schematic block diagram showing the general arrangement ofa projection apparatus having multiple color channels and multiple setsof projection optics for image projection;

FIG. 3B is a schematic block diagram showing the general arrangement ofa projection apparatus having multiple color channels combined to use asingle set of projection optics for image projection;

FIG. 4 is a schematic showing beam alignment with solid-state laserarrays using reflective surfaces;

FIG. 5A is a schematic side-view diagram showing the use of alight-redirecting prism for combining illumination from multiplesolid-state laser light arrays;

FIG. 5B is a perspective of the light-redirecting prism of FIG. 7A;

FIG. 6 is a schematic side view of a light-redirecting prism thataccepts light from two different sides;

FIG. 7 is a perspective of a beam alignment chamber for combining lightfrom multiple solid-state laser arrays in one embodiment;

FIG. 8 is a perspective of a beam alignment chamber with top coverremoved and showing laser array sources on both sides;

FIG. 9 is a perspective of a beam alignment chamber showing the relativepositions of reflectors mounted on the base and cover;

FIG. 10 is a perspective of a beam alignment chamber with one side andtop cover not visible, showing one type of independently adjustablemirror mount;

FIG. 11 is a plan view showing a side wall of the beam alignmentchamber;

FIG. 12 is a plan view showing the portions of the output beam frommultiple aligned laser arrays;

FIG. 13 is a top view showing representative light paths for one of thetop-mounted and one of the base-mounted reflectors;

FIG. 14 is a top view showing equalized optical path lengths for aportion of the beam alignment chamber;

FIG. 15 is a perspective that shows how equalized optical path lengthscan be used to simplify optics for conditioning the output beam; and

FIG. 16 is a perspective of kinematic mirror mounts with independentlyadjustable pitch and yaw in one embodiment.

DETAILED DESCRIPTION OF THE INVENTION

The present description is directed in particular to elements formingpart of, or cooperating more directly with, apparatus in accordance withthe invention. It is to be understood that elements not specificallyshown or described may take various forms well known to those skilled inthe art.

Figures shown and described herein are provided to illustrate principlesof operation according to the present invention and are not drawn withintent to show actual size or scale. Because of the relative dimensionsof the component parts for the laser array of the present invention,some exaggeration is necessary in order to emphasize basic structure,shape, and principles of operation.

Embodiments of the present invention address the need for improved lightintensity for each color channel in an electronic image projector. Inorder to better understand the present invention, it is instructive todescribe the overall context within which apparatus and methods of thepresent invention can operate. The schematic diagrams of FIGS. 3A and 3Bshow two basic architectures for the projection apparatus 10 of FIG. 1.Embodiments of the present invention can be suitably employed as part ofthe illumination system for either of these basic architectures.

Turning first to FIG. 3A, there is shown a basic arrangement forprojection apparatus 10 that is used in a number of embodiments of thepresent invention. Three light modulation channels 40 r, 40 g, and 40 bare shown, each modulating one of the primary red, green, or blue (RGB)colors from an illumination system 42. In each light modulation channel40 r, 40 g, and 40 b, an optional lens 50 may direct light into anoptional polarization maintaining light guide 52. At the output of lightguide 52, or otherwise receiving light from lens 50, a lens 54 thendirects light through an integrator 51, such as a fly's eye integratoror integrating bar, for example. This light goes to a spatial lightmodulator 60 that is part of an image forming system for projectorapparatus 10. Spatial light modulator 60 is typically amicro-electromechanical systems (MEMS) device, such as a DLP or othertype of reflective MEMS component, including any of the types of MEMSmodulator components that modulate light by reflection or bydiffraction. These devices can be considered as “polarization stateneutral”, since they do not modulate light at each pixel by modulatingthe polarization state of the pixel; any change to the polarizationstate of the incident light for any pixel is inadvertent, a function ofits incident angle when reflected from the MEMS surfaces for that pixel.The incident angle of light to the MEMS spatial light modulator can beadjusted to minimize any unwanted polarization effects. Projectionoptics 70, indicated generally in a dashed outline in FIG. 3A due to itsmany possible embodiments, then direct the modulated light to a displaysurface 80.

Turning next to FIG. 3B, a color combiner 76 is used for combining themodulated light from each color light modulation channel 40 r, 40 g, 40b onto a common output axis A for projection. Color combiner 76 may bean assembly of prisms or dichroic surfaces, such as an X-cube or othercombining device, familiar to those skilled in the electronic imagingarts.

Using either of these two basic imaging architectures, the function ofillumination system 42 is the same: combining the light from two or morelaser arrays, aligning the individual light beams along a commonillumination path. FIG. 4 shows one approach for combining multiplelight source arrays 44 and 44′ to form a larger array with alignedcollimated beams. One or more interspersed mirrors 46 may be used toplace the optical axis of additional light source arrays 44′ in linewith solid-state light source array 44. However, it can be appreciatedthat heat and spacing requirements may limit how many light sourcearrays 44 can be stacked in this manner. In addition, the spacingbetween beam sources is also constrained with this solution.

The side and perspective views of FIGS. 5A and 5B show an improvedapproach to beam combination using a light redirecting prism 48. Here,illumination system 42 combines laser light from four solid-state lightarrays 44, concentrated within an even smaller area than the arrayarrangement of FIG. 4. Light-redirecting prism 48 has an incident face32 that accepts light emitted from light source arrays 44 comprised oflasers 26 in an emission direction D1. Light is redirected through anoutput face 34 in an output direction D2 that is substantiallyorthogonal to emission direction D1. Light redirecting prism 48 has aredirection surface 36 that has light-redirecting facets 38.Light-redirecting facets 38 are at an oblique angle relative to emissiondirection D1 and provide Total Internal Reflection (TIR) to lightemitted from lasers 26. When staggered as shown in FIGS. 5A and 5B,these features help to narrow the light path for this illumination,providing a narrower light beam. As FIG. 5B shows, light source arrays44 each have multiple lasers 26 that extend in a length direction L.Light-redirecting facets 38 and other facets on redirection surface 36also extend in direction L.

The cross-sectional side view of FIG. 6 shows another embodiment oflight-redirecting prism 48 in illumination system 42 that provides aneven more compact arrangement of illumination than the embodiment shownin FIGS. 5A and 5B for using light source arrays. In this embodiment,light-redirecting prism 48 has two redirection surfaces 36, acceptinglight from light source arrays 44 that are facing each other, withopposing emission directions D1 and D1′. Each redirection surface 36 hastwo types of facets: a light-redirecting facet 38 and an incidence facet28 that is normal to the incident light from the corresponding lightsource array 44.

The overall approach using light redirecting prism 48 offers animprovement to conventional methods for forming a light beam ofcollimated rays, but has some limitations. One problem relates toalignment difficulties. With this light combination geometry, each ofthe light source arrays 44 must be very precisely aligned in order toproperly aim the light beams in the proper direction. This requires thateach laser source be precisely registered or custom aligned to theprism, placing considerable demands on laser mounting mechanics. Sincehigh power lasers generate significant heat, the need to remove thisheat further complicates mounting and alignment. While this arrangementallows some measure of scalability, this is limited by how closelytogether light source arrays 44 can be placed. In addition,light-redirecting prism 48 can be difficult to mount and changingtemperatures of the prism material under operating conditions can causeunwanted birefringence and other problems. The need to properly shieldthe laser light adds a further complication.

The present invention addresses the need for an improved light sourcethat combines collimated light from a plurality of lasers of eachwavelength by providing a beam alignment chamber for each color channel.With respect to FIGS. 3A and 3B, the beam alignment chamber of thepresent invention is part of the illumination system 42 within eachcorresponding light modulation channel 40 r, 40 g, 40 b.

The perspective of FIG. 7 shows a beam alignment chamber 100 thatcombines and interleaves the output beams of several solid-state lightsource arrays, such as laser array sources, in order to generate acomposite light beam formed from a plurality of light beams, shown inthis embodiment as collimated, all parallel to an illumination axis A1that extends in the length direction of beam alignment chamber 100.FIGS. 8, 9, 10, and 11 show various details of beam alignment chamber100 construction in one embodiment.

Referring to the different views of FIGS. 7-11, beam alignment chamber100 has a base 110 with front and back edges 112 and 114, and first andsecond side edges 116 and 118. There are opposed first and second sidewalls 120 and 122 along first and second side edges 116 and 118,respectively, and extending along the length of beam alignment chamber100, and a front wall 132. Side openings 124 are provided within sidewalls 120 and 122 for light beams from array light sources 140 to enterthe beam aligment chamber 100. Light exiting the beam alignment chamber100 passes through an output opening 128 in front wall 132. A pluralityof reflectors 130 are disposed at an oblique angle with respect to sidewalls 120 and 122 to direct light beams from a corresponding array lightsource 140 to exit the beam alignment chamber 100 through the outputopening 128, forming an aligned two-dimensional array of parallel lightbeams. Reflectors 130 mount to base 110 and, optionally, to a cover 126.Each reflector 130 has its own independent adjustment for pitch and yaw,allowing precision alignment of the light beams from each array lightsource 140. FIG. 7 shows a plurality of adjustment access holes 154provided in cover 126 for this purpose. One or more adjustment accessholes 154 can alternately be provided along base 110. In the embodimentof FIG. 7, all pitch and yaw adjustments for both top- and base-mountedreflectors can be accessed from cover 126.

The beam alignment chamber 100 embodiment shown in FIGS. 7-11 has amodular configuration and squared cylindrical shape, with side edges 116and 118 of base 110 intersecting with first and second side walls 120and 122. This arrangement is advantaged for its compactness and relativeease of mounting. However, other side wall 120 and 122 arrangements arepossible. In an alternate embodiment of the present invention, base 110is some other shape, such as triangular, for example and has only afront edge and first and second side edges. In another embodiment, base110 is part of a larger chassis structure and extends beyond side walls120 and 122. The function of cover 126 may alternately be provided bysome other part of a chassis or other structure.

The perspective of FIG. 8 shows beam alignment chamber 100 populatedwith twelve array sources 140, six along each side wall 120 and 122. Thetwelve array sources 140 are paired with twelve reflectors 130, mountedon both base 110 and cover 126. The aligned output beams from each ofarray sources 140 then provide an output light beam array 150 that,considered in cross-section, forms an aligned two-dimensional array oflight beams where the contribution of each array source 140 is centeredover a particular portion of the beam. In embodiments of the presentinvention, the output light emitted as output light beam array 150 fromoutput opening 128 has a pattern that is advantageous for providing anillumination beam, with dimensions adapted for the aspect ratio of thespatial light modulator that is used (for example, spatial lightmodulator 60 in FIGS. 3A, 3B).

The perspective of FIG. 9 shows the positions of cover-mounted andbase-mounted reflectors 130 for the populated beam alignment chamber 100of FIG. 8. The perspective view of FIG. 10 shows an embodiment usingmirror mounts 200, described in more detail subsequently.

The plan view of FIG. 12 shows how the aligned light beams from eachsolid-state light array source 140 in beam alignment chamber of FIG. 8form an output light beam array 150 as an aligned two-dimensional arrayof parallel light beams that has a rectangular aspect ratio. For theembodiment of beam alignment chamber 100 shown in FIGS. 7-11, the arraylight sources 140 that are paired with base-mounted reflectors 130 formthe lower portion of output light beam array 150, with its six compositeparts, aligned array beams 142 a, 142 b, 142 c, 142 d, 142 e and 142 f.Similarly, array light sources 140 that are paired with cover-mountedreflectors 130 form the upper portion of output light beam array 150,with aligned array beams 144 a, 144 b, 144 c, 144 d, 144 e and 144 f.This same relationship for shaping the output illumination is shown inFIGS. 7 and 8. (The output shown as output light beam array 150 in FIG.7 represents only that portion of the output that is provided frombased-mounted reflectors 130. Note that only three of the six arraysources 140 are shown in position in FIG. 7.) Each of the aligned arraybeams 142 a-142 e and 144 a-142 e comprise an array of individual lightbeams 148 from a corresponding array light source 140.

FIG. 13 is a top view of beam alignment chamber 100 showing the pairingof each array source 140 with its corresponding reflector 130 forforming output light beam array 150 in one embodiment. Array lightsources 141 a, 141 b, 141 c, 141 d, 141 e and 141 f mount on cover 126and form corresponding aligned array beams 144 a, 144 b, 144 c, 144 d,144 e, and 144 f, respectively, of FIG. 12. Similarly, array lightsources 140 a, 140 b, 140 c, 140 d, 140 e and 140 f mount on base 110and form corresponding aligned array beams 142 a, 142 b, 142 c, 142 d,142 e, and 142 f, respectively, of FIG. 12. The beam paths for topmounted array source 141 c and base-mounted array source 140 d aretraced in FIG. 13. Array source 140 d is paired with a base-mountedreflector 130 d. Similarly, array source 141 c is paired with acover-mounted reflector 131 c.

Although laser light sources in array light sources 140 may becollimated, there are some laser types that have significant beamdivergence. Typically, beam divergence at the laser source is atdifferent angles in orthogonal directions. Beam divergence is oftencorrected in at least one orthogonal direction using a cylindrical lenselement or an array of lenslets or other optical elements mounted at ornear the output of the laser emitter itself While both beam divergencedirections may be corrected with a bi-cylindrical lens, two lenses inseries having respectively orthogonal curvatures, these lenses areexpensive and are difficult to align properly. Therefore, with respectto the line of laser emitters 148 in FIG. 12, beam divergence at thelaser array may be uncorrected with respect to both axes, but istypically corrected only in the direction of the x-axis. Beam divergencein the orthogonal direction, along the y axis shown in FIG. 12, alsoneeds correction.

The conventional solution for correcting y-axis beam divergence is toprovide a collimating cylindrical lens at the output of each array. Thissolution, however, is costly, adding twelve additional lenses to thecomponent count for beam alignment chamber 100 shown in FIGS. 7-11, forexample. Optionally, reflectors 130 can be cylindrical in shape, ratherthan planar, formed to correct for beam divergence. However, each ofthese cylindrical mirrors would be substantially more expensive than thecommon planar mirror depicted in FIGS. 8-11. Moreover, adjustment forpitch and yaw would be further complicated by surface curvature.

In contrast to the cost and complexity of conventional approaches tothis problem, embodiments of the present invention provide correctionfor beam divergence by making the optical path distance for each lasersource equal, thus allowing the use of only a single cylindrical lens inthe output light beam array since the divergence characteristics of eachlight beam will be consistent. Referring to FIGS. 14 and 15, there areshown top and perspective views, respectively, of beam alignment chamber100 with equal optical path distances and a single correctivecylindrical lens 152. In the embodiment shown in FIGS. 14 and 15, beampaths are interleaved, passing through each other using an arrayedarrangement of staggered reflectors that differs from that shown in FIG.13, for example. FIG. 14 shows equalized optical path distances for aportion of the array sources. FIG. 15 shows beam divergence in thedirection of the linear array of emitters for each of a set of arraylight sources 141 a, 141 b, 141 c, 141 d, 141 e and 141 f. When theselight emitters have equal optical path distances, the angle of the lightthat is incident on cylindrical lens 152 from each source issubstantially the same. Cylindrical lens 152 can then providecollimation along the divergence axis. In this manner, separatecollimating optics are not required for each individual array lightsource.

Cylindrical lens 152 is only a representative configuration. In general,there can be more than one optical element in the path of the alignedlight beams and providing collimation to the output light. For example,crossed cylindrical lenses can be used to correct the divergence in eachof the two orthogonal axes. In an alternate embodiment, a separatecollimating lens (not shown) is provided in the path of each arraysource 140, so that the light that is output from output opening 128 iscollimated without the need for cylindrical lens 152 or othercollimation optics as shown in FIG. 15.

Beam alignment chamber 100 uses multiple reflectors 130, each of whichcan be separately adjusted for pitch and yaw. Referring to FIG. 16, abase-mounted mirror mount 200 having this adjustment capability isshown. A reflective element 202 has a supporting frame 204 withadjustable coupling to a base member 210. Pitch adjustment is about thex-axis using the axes assignments shown in FIG. 16. Yaw adjustment isabout the y-axis. It can be appreciated that a number of differentmirror mount embodiments are possible for use within beam alignmentchamber 100.

Beam alignment chamber 100 of the present invention can be used as theillumination system component of a projector apparatus, such as anapparatus having the basic architecture described earlier with referenceto projector apparatus 10 in FIGS. 3A and 3B. The light output from beamalignment chamber 100 can be further conditioned, such as beinguniformized using an integrator bar or other device, to provide a moreuniform beam of illumination for modulation. Reflectors 130 can bemounted along a single plane, such as in the base-mounted embodimentshown in FIG. 7, or in two planes, as in the cover-mounted andbase-mounted embodiment shown in FIG. 8. For high efficiency, reflectors130 can be dichroic surfaces.

Using the beam alignment chamber of the present invention allows acompact packaging arrangement for grouping together the output lightfrom multiple laser arrays, without introducing angular content andthereby effectively increasing the etendue of the illumination systemfor a projection apparatus. The beam alignment chamber is highlymodular, allowing individual laser arrays to be replaced without theneed for complete realignment of multiple components in the opticalpath. Adjustments for beam alignment are made at the reflector, ratherthan by repositioning or otherwise adjusting the laser apparatus itself.

Array light sources 140 can be packaged in modular fashion and fitteddirectly against openings 124 in side walls 120 and 122, as shown, forexample, in FIG. 7. This arrangement can help to reduce stray light andmay be of particular value where shielding from laser light is importantto the design of an illumination system.

The invention has been described in detail with particular reference tocertain preferred embodiments thereof, but it will be understood thatvariations and modifications can be effected within the spirit and scopeof the invention. For example, where laser arrays are described in thedetailed embodiments, other solid-state emissive components could beused as an alternative. Supporting lenses and other optical componentsmay also be added to each optical path. Various types of sensors can bedeployed at one or more positions within the projector in order to sensethe light intensity in each color channel. Thus, what is provided is anapparatus and method for aligning solid state illumination sources.

PARTS LIST

-   10. Projector apparatus-   12. Light source-   14. Prism assembly-   18. Optics-   20, 20 r, 20 g, 20 b. Spatial light modulators-   26. Laser-   28. Incidence facet-   30. Projection lens-   32. Incident face-   34. Output face-   36. Redirection surface-   38. Light-redirecting facet-   40 r, 40 g, 40 b. Light modulation channels-   42. Illumination system-   44, 44′, 44 a, 44 b. Light source arrays-   46. Mirror-   48. Light redirecting prism-   50. Lens-   51. Integrator-   52. Light guide-   54. Lens-   60. Spatial light modulator-   70. Projection optics-   76. Color combiner-   80. Display surface-   84. Dichroic surface-   100. Beam alignment chamber-   110. Base-   112. Front edge-   114. Back edge-   116. First side edge-   118. Second side edge-   120. First side wall-   122. Second side wall-   124. Side opening-   126. Cover-   128. Output opening-   130. Reflector-   130 d. Base-mounted reflector-   131 c. Cover-mounted reflector-   132. Front wall-   140, 140 a, 140 b, 140 c, 140 d, 140 e, 140 f. Array light sources-   141 a, 141 b, 141 c, 141 d, 141 e, 141 f. Array light sources-   150. Output light beam array-   142 a, 142 b, 142 c, 142 d, 142 e, 142 f. Aligned array beams-   144 a, 144 b, 144 c, 144 d, 144 e, 144 f. Aligned array beams-   148. Light beam-   150. Output light beam array-   152. Cylindrical lens-   154. Adjustment access hole-   200. Mirror mount-   202. Reflective element-   204. Frame-   210. Base member-   A, A1. Axis-   D1, D1′. Emission direction-   D2. Output direction-   x, y. Axis

What is claimed is:
 1. A beam alignment chamber extending in a lengthdirection comprising: a base having a front edge, and two side edges;first and second opposed side walls connected to the base, and extendingalong the length of the base; a front wall located at the front edge ofthe base having an output opening; a plurality of arrays of lightsources located outside the beam alignment chamber disposed to directlight beams into the beam alignment chamber through the first or secondside walls; and a plurality of reflectors mounted on the base within thebeam alignment chamber, each having independent yaw and pitchadjustments, each reflector being paired with a corresponding array oflight sources, the reflectors being disposed to direct the light beamsalong the length of the beam alignment chamber through the outputopening forming an aligned two-dimensional array of parallel lightbeams.
 2. The beam alignment chamber of claim 1 wherein the arrays oflight sources are disposed to direct light through both the first andsecond side walls.
 3. The beam alignment chamber of claim 1 furtherincluding a cover spaced apart from the base and connected to the firstand second side walls, together with a plurality of reflectors mountedto the cover within the beam alignment chamber, each having independentyaw and pitch adjustments, each paired with a correspondingone-dimensional array of light sources, the cover-mounted reflectorsbeing disposed to direct the light beams along the length of the beamalignment chamber through the output opening, and, together with thelight beams associated with the base-mounted reflectors, forming thealigned two-dimensional array of parallel light beams.
 4. The beamalignment chamber of claim 3 wherein adjustment holes are provided inthe cover to access the independent yaw and pitch adjustments for boththe cover-mounted and base-mounted reflectors.
 5. The beam alignmentchamber of claim 1 wherein the optical distance between each lightsource and the output opening is substantially equal for each of thelight beams.
 6. The beam alignment chamber of claim 5 wherein each lightbeam entering the beam combining chamber is uncorrected for divergencewith respect to at least one axis, and further including one or moreoptical elements positioned in the optical path of the alignedtwo-dimensional array of light beams disposed to correct the beamdivergence with respect to at least one axis.
 7. The beam alignmentchamber of claim 6 wherein the corrected aligned two-dimensional arrayof light beams is collimated.
 8. The beam alignment chamber of claim 6wherein the one or more optical elements comprise a cylinder lensproviding correction for the beam divergence with respect to one axis.9. The beam alignment chamber of claim 6 wherein the one or more opticalelements comprise a pair of crossed cylinder lenses providing correctionfor the beam divergence with respect to two axes.
 10. The beam alignmentchamber of claim 1 wherein each light beam entering the beam combiningchamber is uncorrected for divergence with respect to at least one axis,and wherein the reflectors are cylindrical reflectors that correct thebeam divergence with respect to one axis.
 11. The beam alignment chamberof claim 1 wherein the light sources are laser light sources.
 12. Thebeam alignment chamber of claim 1 wherein the beam alignment chamber isa component of a laser source system that provides a two-dimensionalarray of parallel laser beams for use in a laser projection system, andwherein the laser projection system further comprises: an illuminationsystem configured to uniformize laser light it receives; an imageforming system configured to interact with laser light that has beenboth uniformized by the illumination system; and a projection systemconfigured to project the laser light image onto a viewing screen.
 13. Amethod for aligning a plurality of light beams comprising: forming achamber between at least opposing first and second side walls thatextend from a base and having an output; mounting a plurality ofreflectors inside the chamber along the base, spaced apart between thefirst and second side walls, wherein each reflector has independent yawand pitch adjustments and is disposed at an oblique angle relative tothe side walls; and providing a plurality of arrays of light sourcespositioned outside the chamber, each array of light sources producing anarray of light beams that are directed into the chamber through one ofthe first or second side walls, each array of light sources being pairedwith a corresponding reflector, the reflectors being disposed to reflectthe array of light beams from the paired array of light sources towardthe output of the chamber.
 14. The method of claim 13 further comprisingproviding a cover for the chamber and mounting one or more additionalreflectors inside the chamber along the cover, spaced apart between thefirst and second side walls, and providing a plurality of additionalarrays of light sources, each additional array of light sourcesproducing an array of light beams and being paired with a correspondingadditional reflector, the additional reflectors being disposed toreflect the array of light beams from the paired additional array oflight sources toward the output of the chamber.